This page is a placeholder. All examples on this page are currently AI-generated and are not correct. This documentation will be completed in the future with accurate, tested examples.
Overview
Opcode: 0x61
Introduced: Frontier (EVM genesis)
PUSH2 pushes a 2-byte immediate value from the bytecode onto the stack. The 2 bytes immediately following the opcode are read and zero-padded to 256 bits.
Specification
Stack Input:
Stack Output:
value (uint256, 2 bytes from bytecode)
value = read_bytes(pc + 1, 2) // Big-endian
stack.push(value)
pc += 3
Behavior
PUSH2 reads 2 bytes from bytecode starting at position pc + 1, interprets them as a big-endian unsigned integer, and pushes the result onto the stack.
Key characteristics:
- Reads exactly 2 bytes following opcode
- Big-endian byte order (most significant byte first)
- Zero-padded to 256 bits if less than 32 bytes
- InvalidOpcode if insufficient bytecode remaining
- PC advances by 3 (opcode + data)
Examples
Basic Usage
import { handler_0x61_PUSH2 } from '@tevm/voltaire/evm/stack/handlers';
import { createFrame } from '@tevm/voltaire/evm/Frame';
// Bytecode with PUSH2
const bytecode = new Uint8Array([
0x61, // PUSH2
0x01, 0x02 // 2 bytes: 0102
]);
const frame = createFrame({
bytecode,
pc: 0,
stack: [],
gasRemaining: 1000n
});
const err = handler_0x61_PUSH2(frame);
console.log(frame.stack); // [0x0102000000000000000000000000000000000000000000000000000000000000n]
console.log(frame.pc); // 3
console.log(frame.gasRemaining); // 997n (3 gas consumed)
Solidity Compilation
contract Example {
// Function selectors use PUSH4
function transfer() public {
// PUSH4 0xa9059cbb (4-byte selector)
}
}
Assembly Usage
assembly {
// Push 2-byte value
push2 0xffff
// Example: 2-byte constant
}
Gas Cost
Cost: 3 gas (GasFastestStep)
All PUSH1-32 instructions cost the same despite different data sizes. Bytecode size impact:
- PUSH2: 3 bytes (1 opcode + 2 data)
- PUSH32: 33 bytes (1 opcode + 32 data)
Comparison:
| Opcode | Gas | Bytes | Use Case |
|---|
| PUSH0 | 2 | 1 | Zero constant (Shanghai+) |
| PUSH1 | 3 | 2 | Small numbers (0-255) |
Common Usage
2-Byte Constants
assembly {
// 2-byte literal
push2 0xabab
}
Big-Endian Encoding
// Bytecode: PUSH2 01 02
// Reads as: 0x0102
// Most significant byte first
// Byte 0: 0x01 (highest significance)
// Byte 1: 0x02 (lowest significance)
Implementation
/**
* Read immediate data from bytecode for PUSH operations
*/
function readImmediate(bytecode: Uint8Array, pc: number, size: number): bigint | null {
if (pc + 1 + size > bytecode.length) {
return null;
}
let result = 0n;
for (let i = 0; i < size; i++) {
result = (result << 8n) | BigInt(bytecode[pc + 1 + i]);
}
return result;
}
/**
* PUSH2 opcode (0x61) - Push 2 bytes onto stack
*
* Stack: [] => [value]
* Gas: 3 (GasFastestStep)
*/
export function handler_0x61_PUSH2(frame: FrameType): EvmError | null {
const gasErr = consumeGas(frame, FastestStep);
if (gasErr) return gasErr;
const value = readImmediate(frame.bytecode, frame.pc, 2);
if (value === null) {
return { type: "InvalidOpcode" };
}
const pushErr = pushStack(frame, value);
if (pushErr) return pushErr;
frame.pc += 3;
return null;
}
Edge Cases
Insufficient Bytecode
// Bytecode ends before 2 bytes read
const bytecode = new Uint8Array([0x61, 0x01]); // Only 1 byte instead of 2
const frame = createFrame({ bytecode, pc: 0 });
const err = handler_0x61_PUSH2(frame);
console.log(err); // { type: "InvalidOpcode" }
Stack Overflow
// Stack at maximum capacity
const frame = createFrame({
stack: new Array(1024).fill(0n),
bytecode: new Uint8Array([0x61, 0x00, 0x00])
});
const err = handler_0x61_PUSH2(frame);
console.log(err); // { type: "StackOverflow" }
Out of Gas
// Insufficient gas
const frame = createFrame({
gasRemaining: 2n, // Need 3 gas
bytecode: new Uint8Array([0x61, 0xff, 0xff])
});
const err = handler_0x61_PUSH2(frame);
console.log(err); // { type: "OutOfGas" }
Maximum Value
// All bytes 0xFF
const bytecode = new Uint8Array([0x61, 0xff, 0xff]);
const frame = createFrame({ bytecode, pc: 0 });
handler_0x61_PUSH2(frame);
console.log(frame.stack[0]); // 0xffff000000000000000000000000000000000000000000000000000000000000n
References
